A device, system, and method for vaporizing substances in a pod, utilized for inhalation by a user. The device includes components to measure the content and dosage pods containing substances, among other features. The device includes a graphical user interface that may be integrated with the device or implemented through a mobile device, which allows the user to transmit user data to a remote database and/or healthcare provider for personal and clinical data collection. The user data can be used for enhancing personal treatment or clinical research.

A ventilation gas cooling apparatus is configured in a modular form adapted for selective removable engagement to a ventilator. The apparatus includes a gas inlet port, a gas delivery port, a pressure sensing port, and a thermoelectric cooler. The inlet port is fluidly connectible to a source of therapeutic breathing gas at an external end and is fluidly connectible to an inlet of the ventilator at an internal end. The delivery port is fluidly connectible to a patient circuit at an external end and is fluidly connectable to an outlet of the ventilator at an internal end. The pressure sensing port is fluidly connectible to both a pressure sensing port of the ventilator and to the patient circuit. The apparatus may further include a cooling fluid system operative to circulate either a gas or liquid coolant along at least a portion of a multi-lumen tube integrated into the patient circuit.

Heat treatment apparatus for inactivating viruses in blood includes a series of four tubing coils with connectors at the opposite ends of the series for connecting the tubing to a blood source and a blood destination, a microwave heating chamber arranged to receive the first coil of the series, a dwell chamber to receive the second coil of the series, a cooling chamber adapted to receive the third coil of the series, and a microwave reheating chamber to receive the fourth coil of the series, with the first, second, and fourth chambers employing microwave energy for heating the blood as it flows within the coils and providing a radiometer circuit for monitoring the temperatures of the blood in the first, second, and fourth coils to produce first, second, and fourth temperature signals in response thereto, which is responded to by a controller to control the energy producing means to impart a selected time/temperature profile to the blood flowing through the tubing and to deliver that blood at a selected delivery temperature.

A drug delivery pump includes a dosing chamber (16) for delivering a substance (18) therefrom, pushing apparatus, and a thermal energy source (14) arranged to cause a sufficient change in temperature in a portion of the pushing apparatus so that the pushing apparatus imparts a pushing force against the substance to cause the substance to be delivered from the dosing chamber. A controller (90) controls delivery of the substance from the dosing chamber. A thermal insulator (24) thermally insulates the substance in the dosing chamber from the thermal energy source.

A respiratory device, such as a ventilator, for use in treating respiratory disorders and for preventing respiratory disorders. The respiratory device is configured to be powered from a range of different power sources including an internal battery, an external battery, AC power source or a DC power source. The device may be electrically connectable to a plurality of external batteries in a series and the power from each external battery is used sequentially along the series. A controller of the respiratory device is configured to detect the connection of the different power sources and control use of the different power sources using a power priority scheme. The controller may determine an estimate of the total available battery capacity from all the electrically connected batteries and display the total battery capacity on a user interface display of the device.

A centrifugal pump includes a rotating shaft, a pump substrate, a housing and an impeller. The pump substrate has a driving unit configured to rotate the rotating shaft. The housing has an inlet and an outlet and forms a pump chamber with the pump substrate. A body fluid sucked from the inlet flows through the pump chamber. The impeller is housed in the pump chamber and is configured to use the rotating shaft as an axis. The pump substrate has a magnetism generating source. The rotating shaft protrudes into the pump chamber from the pump substrate, and is pivotally supported on the pump substrate. A magnetic fluid is disposed on at least one of spaces formed among the pump substrate, the rotating shaft, and the impeller.

Various handheld medical dispensing configurations and methods including the following: Handheld medical dispensing system comprises a syringe, which has a plunger, releasably mounted to syringe actuation apparatus, the apparatus having an actuator configured such that it can move the plunger more than once to dispense a plurality of amounts of substance from the syringe and having a housing adapted for singled handed administration of an injection.

A portable vein viewer apparatus may be battery powered and hand-held to reveal patient vasculature information to aid in venipuncture processes. The apparatus comprises a first laser diode emitting infrared light, and a second laser diode emitting only visible wavelengths, wherein vasculature absorbs a portion of the infrared light causing reflection of a contrasted infrared image. A pair of silicon PIN photodiodes, responsive to the contrasted infrared image, causes transmission of a corresponding signal. The signal is processed through circuitry to amplify, sum, and filter the outputted signals, and with the use of an image processing algorithm, the contrasted image is projected onto the patient's skin surface using the second laser diode. Revealed information may comprise vein location, depth, diameter, and degree of certainty of vein locations. Projection of vein images may be a positive or a negative image. Venipuncture needles may be coated to provide visibility in projected images.

The subject technology pertains to an herbal vaporization apparatus including an electric heat base comprising a glass pass-through tube, and a hydratube having a first end a second end, wherein the hydratube is configured to be removably coupled with the electric heat base at the second end to place the hydratube in fluidic communication with the glass pass-through tube. The electric heat base can be configured to be coupled to the hydratube such that the hydratube is vertically mounted on top of the electric heat base. The electric heat base can include a glass pass-through tube including a plurality of chambers separated by constrictions and configured to receive and transmit a volume of gas, and a heating element disposed adjacent to the glass pass-through tube to heat the volume of gas received by the glass pass-through tube. Furthermore, the herbal vaporization apparatus can also include an herbal containment unit.

This invention provide novel compositions, methods and devices for sustained drug delivery. The compositions can include a fluid carrier; a plurality of first polymeric microparticles having a bioactive agent dispersed in the fluid carrier; and a plurality of second polymeric microparticles having a visualization agent dispersed in the fluid carrier with the first microparticles. Alternative compositions can include: a fluid carrier; and a plurality of polymeric microparticles having a bioactive agent encapsulated therein and a visualization agent on a surface of the polymeric microparticles, the plurality of polymeric microparticles being dispersed in the fluid carrier. The microencapsulated sustained drug delivery compositions are deposited using oscillating needle apparatus oscillating at 10-12000 minutes per minutes at an amount of 1.0E-03 mL to 1.0E-16 mL per injection.